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Kinetics of Glutathione Depletion and Antioxidant Gene Expression as Indicators of Chemical Modes of Action Assessed in vitro in Mouse Hepatocytes with Enhanced Glutathione Synthesis Fjodor Melnikov, Dianne Botta, Collin C. White, Stefanie C Schmuck, Matthew Winfough, Christopher M Schaupp, Evan Gallagher, Bryan W Brooks, Edward Spencer Williams, Philip Coish, Paul T. Anastas, Adelina Voutchkova, Jakub Kostal, and Terrance J. Kavanagh Chem. Res. Toxicol., Just Accepted Manuscript • DOI: 10.1021/acs.chemrestox.8b00259 • Publication Date (Web): 14 Dec 2018 Downloaded from http://pubs.acs.org on December 16, 2018

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is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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Kinetics of Glutathione Depletion and Antioxidant Gene Expression as Indicators of Chemical Modes of Action Assessed in vitro in Mouse Hepatocytes with Enhanced Glutathione Synthesis Fjodor Melnikov§$, Dianne Botta⟂$, Collin C. White⟂, Stefanie C. Schmuck⟂, Matthew Winfoughȼ, Christopher M. Schaupp⟂, Evan Gallagher⟂, Bryan W. Brooks∥, Edward Spencer Williams∥, Philip Coish§, Paul T. Anastas§⟠, Adelina Voutchkovaȼ,, Jakub Kostalȼ*, Terrance J. Kavanagh⟂*.

§Yale

School of Forestry and Environmental Sciences, Yale University, New Haven, CT 06520

⟂Department

of Environmental and Occupational Health Sciences, University of Washington,

Seattle, WA 98195 ∥Department

of Environmental Science, Baylor University, Waco, TX 76798

ȼDepartment

of Chemistry, George Washington University, Washington, DC 20052

⟠School

$These

*To

of Public Health, Yale University, New Haven, CT 06520

authors contributed equally to this work.

whom correspondence should be addressed.

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Abstract Here we report a vertically integrated in vitro – in silico study that aims to elucidate the molecular initiating events involved in the induction of oxidative stress (OS) by seven diverse chemicals (cumene hydroperoxide, t-butyl hydroperoxide, hydroquinone, t-butyl hydroquinone, bisphenol A, Dinoseb, and perflourooctanoic acid). To that end, we probe the relationship between chemical properties, cell viability, glutathione (GSH) depletion and antioxidant gene expression. Concentration-dependent effects on cell viability were assessed by MTT assay in two Hepa-1 derived mouse liver cell lines: a control plasmid vector transfected cell line (Hepa-V), and a cell line with increased glutamate-cysteine ligase (GCL) activity and GSH content (CR17). Changes to intracellular GSH content and mRNA expression levels for the Nrf2-driven antioxidant genes Gclc, Gclm, heme oxygenase-1 (Hmox1), and NADPH quinone oxidoreductase-1 (Nqo1) were monitored after sub-lethal exposure to the chemicals. In silico models of covalent and redox reactivity were used to rationalize differences in activity of quinones and peroxides. Our findings show CR17 cells were generally more resistant to chemical toxicity and showed markedly attenuated induction of OS biomarkers; however, differences in viability effects between the two cell lines were not the same for all chemicals. The results highlight the vital role of GSH in protecting against oxidative stress-inducing chemicals, as well as the importance of probing molecular initiating events in order to identify chemicals with lower potential to cause oxidative stress.

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Introduction The 4th principle of green chemistry emphasizes the need to mitigate chemical toxicity through rational design.1–4 Computational methods, like property-activity models and design guidelines, provide the framework for a powerful approach for chemical assessment, design, and substitution.5–7 The fundamental principle that informs development of predictive structure- and property-activity relationships (SARs and PARs), as highlighted in the Organization for Economic Cooperation and Development (OECD) principles, calls for attributes used to describe chemical space to be directly relevant to toxicological mechanisms, or modes of action (MoA).6,8,9 To that end, it is necessary to explicitly identify key toxicodynamic interactions between a chemical and its potential biological targets prior to any model development. These interactions are termed molecular initiating events (MIE);10–12 they initiate a cascade of key events that instigate one or more adverse outcome pathways (AOP).10,13 Given that classical in vivo testing approaches do not readily provide insights into MoAs, additional in vitro, in silico and/or in chimico data are required to identify potential AOPs and MIEs.14–16 Relating MIEs to specific chemical properties and reactivity indices, which are preserved across species, can alleviate interspecies’ variations in AOPs; for example, covalent interactions between exogenous Michael acceptors and biological nucleophiles can be related to in silico reactivity parameters that are broadly applicable.6,17,18 Canonically, exposure to electrophilic stressors can upset intracellular redox homeostasis, creating a state of oxidative stress (OS) and initiate apoptosis and/or necrosis in cell lines. 19–30 On an organism level, OS contributes to a wide range of adverse outcomes, including liver disease31–34 neurodegeneration35–38, cancer39–45, hypertension46–48, atherosclerosis49, ischemia50 and reperfusion injuries.51 To counter OS, cells have evolved highly conserved defense 4 ACS Paragon Plus Environment

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mechanisms; for example, small antioxidant molecules, such as glutathione (GSH) and inducible antioxidant proteins, act as scavengers for electrophiles that give rise to OS. Both GSH and antioxidant protein induction sensors rely largely on sensory amino acids that are modified by electrophilic chemicals and ROS.30,52–56 In biological systems, GSH in conjugations with Glutathione S-transferase (GST) and Glutathione Peroxidase (GPx) enzymes helps scavenge electrophiles, reduce oxidants, and is a critical contributor to electrophile defense systems.55,57 Diminished GSH levels are associated with decreased resistance to OS, and potentially to the formation the oxidation product of GSH, glutathione disulfide (GSSG). GSSG can in turn be either exported from the cell, or reduced back to GSH by the action of GSSG reductase. Inducible response to OS is controlled largely by the nuclear factor erythroid 2-like 2 transcription factor (NFE2L2, aka NRF2).52,58 Under oxidative conditions, electrophiles and reactive oxygen species (ROS) activate NRF2-dependent transcription by modifying cysteine residues on KEAP1 (Kelch-like ECH associated protein 1), which prevents the KEAP1CULLIN-3 dependent ubiquination and subsequent degradation of NRF2.52,59–63 Chemicals that activate NRF2 are generally characterized as being able to (1) permeate through biological membranes; (2) either retain electrophilic activity despite metabolic transformations, or become electrophilic via phase I/phase II metabolism; and (3) covalently modify residues on KEAP1, or oxidize KEAP1 thiols to disulfides. Once activated, NRF2 promotes transcription of multiple stress-response genes by recruiting small MAF proteins to associated antioxidant response elements (ARE).52,61,64 The upregulated mRNAs include NAD(P)H-quinone oxidoreductase (Nqo1), catalytic and modifier subunits of glutamate-cysteine ligase (Gclc and Gclm, respectively), and heme oxygenase-1 (Hmox1).65–67 The proteins encoded by the genes are

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essential for 2-electron reduction of quinones, GSH syntheses, and resistance to radical damage (Figure 1). While much research has been focused on understanding the biological cascades involved in OS response (Figure 1), mechanistic studies have yet to identify characteristic attributes of chemicals that can be related to their ability to participate in the aforementioned MIEs. Here we report a vertically integrated in vitro - in silico study of seven diverse chemicals suspected to cause OS (bisphenol A (BPA), t-butyl hydroperoxide, t-butyl hydroquinone (tBHQ), cumene hydroperoxide, Dinoseb, hydroquinone (HQ), and perflourooctanoic acid (PFOA)) that elucidates and relates chemical toxicity to the effects of these chemicals on intracellular GSH, antioxidant gene expression, and in silico measures of reactivity.

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Methods In these experiments, we assessed the effects of seven model compounds on cell viability, oxidative stress response gene expression, glutathione depletion, and in silico modeling of chemical reactivity. A flow-chart of the experiments performed is given in Figure S1. Experimental Chemicals. Seven model electrophilic compounds (Figure 2) were selected based on their ability to elicit an OS response as demonstrated from previous animal in vitro and in vivo studies.68 Cell Cultures. The cell lines used in these experiments were derived from Hepa-1c1c7 (Hepa-1) cells as previously described.69 CR17 cells (hereafter referred to as CR) are Hepa-1 cells transfected with plasmids designed to enhance the expression of GCLC and GCLM and thus have increased glutamate-cysteine ligase (GCL) activity and GSH content. HepaV cells (hereafter referred to as HV) are Hepa-1 cells transfected with an empty plasmid vector alone and serve as a control with normal GCL expression and GSH levels. For MTT assays, cells were cultured in 96-well tissue culture plates in DMEM/F12 medium with 10% Nu-Serum IV (Corning, Corning NY) supplemented with penicillin (100 IU/ml) and streptomycin (100 g/mL) at 37 oC in a 5% CO2/95% air humidified atmosphere. For GSH level assays, RT-qPCR analyses of gene expression and Western immunoblotting, cells were cultured in 6-well tissue culture dishes. Chemical exposures were carried out when cells were at 70-80% confluency, at varying concentrations and for varying periods of time, depending on the experiment (see below). Cell viability monitored by MTT assay. After treatments, medium was removed, cells were rinsed with PBS, and MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide; 250 µg/mL) was added to each well. Plates were incubated for 45 min at 37 °C, the solution was removed, and the accumulated formazan chromophore in cells was dissolved by adding 100 L 7 ACS Paragon Plus Environment

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DMSO to each well. Absorbance was read at 570 nm on a spectrophotometric plate reader (Spectramax 190, Molecular Devices, San Jose, CA). Sublethal concentrations for mRNA and protein expression, and GSH analyses were chosen based on the concentration-response curves from MTT assays. Monitoring Stress-Response Gene Expression by RT-qPCR and Western Immunoblotting. After chemical treatments, total RNA was extracted from cells using an RNeasy Kit (Qiagen, Valencia, CA). Reverse transcription was performed with Superscript III (Invitrogen, Carlsbad, CA) followed by mRNA expression analysis with TaqMan Real-Time PCR assays (Applied Biosystems, Foster City, CA) on an ABI 7900 analyzer (Applied Biosystems) using primers specific for Gclc, Gclm, Nqo1 and Hmox1 transcripts provided by ThermoFisher (Waltham, MA). Relative levels of mRNA expression were calculated using the Ct method relative to the expression of -Actin mRNA. In order to confirm that CR cells have increased GCL expression relative to that of HV cells, Western immunoblots were done for GCLC and GCLM proteins using b-Actin protein to normalize loading. We also assessed the effects of HQ and PFOA treatment on GCLC and GCLM protein expression using slight modifications of standard methods as previously reported.69 Glutathione Depletion Assay. After treatments, total glutathione levels in cells were analyzed using naphthalene dicarboxaldehyde (NDA) derivatization and spectrofluorometry as previously described.70 Briefly, cells were lysed and sonicated, a portion of the cellular lysate was transferred to microcentrifuge tubes, and proteins were precipitated by sulfosalicylic acid addition and centrifugation. Clarified supernatants were then transferred to black flat bottom 96well microtiter plates. Triscarboxyethylphosphine (TCEP) was added to reduce any low molecular weight disulfides, and NDA solution was then added to derivatize GSH. The samples 8 ACS Paragon Plus Environment

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were adjusted to pH 12 and fluorescence was assessed (472 nm excitation/528 nm emission) using a fluorometric plate reader (SpectraMax Gemini, Molecular Devices) as previously described.70 Data Normalization & Statistical Analysis. Gene expression measured by RT-qPCR and GSH concentrations were quantified with a standard curve and then normalized to the β-actin and total protein concentrations, respectively. To maintain approximately normal distributions for significance testing, the normalized values were log-transformed, producing relative expression (∆E) values, as is common in qPCR analysis methodologies. The change in relative expression for a treatment condition (∆∆E) is calculated by normalizing each (∆E) to the (∆E) for control samples analyzed on the same day. ∆∆E estimates were used for all follow-up inference and significance testing. Statistical differences in mRNA expression and GSH levels between treatments were determined with Student’s t-test. The p-values were corrected for falsediscovery using family-wise error rates. MTT readouts were normalized to corresponding negative control and media-only readouts. Concentration-response curves (CRCs) were fit and absolute concentrations predicting 50 % loss of viability (half maximal activity, designated as AC50) were estimated from the CRCs.71 The relationship between endpoints was investigated with hierarchical clustering using correlation-based distances and Ward’s partitioning method. Cluster stability was evaluated with bootstrap. All analyses were performed in the R statistical environment.72 Multivariate differences in chemical-induced responses across time points or cell lines were assessed using multivariate analysis of variance (MANOVA) with Pillai’s trace statistic that is most appropriate for small samples.73 The MANOVA analysis was performed with base R functions.

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Computational Methods. The energetics of chemical mechanisms contributing to the biological effects of peroxides (chemicals 1 and 2) and hydroquinones (chemicals 3 and 4) were investigated computationally. For peroxides, the O-O bond cleavage is thought to represent the frequent MIE that yields the corresponding tertiary alcohol, which can either undergo beta-scission to generate a reactive aromatic ketone in the case of cumene hydroperoxide or enzymatic dehydration to an alkene, which can be subsequently be oxidized by cytochrome P450s or other monooxygenases (e.g. flavin monooxygenases) to a reactive epoxide (Figure 3).74 In this study, O-O bond dissociation energies were computed at the M06HF/6-31+G(d) level of theory. The M06-HF functional is a special case of hybrid meta GGA with full Hartree-Fock exchange term that is well-suited to handle systems where self-interaction is pathological, e.g. delocalized systems with odd number of electrons. The kinetics of 1,1-dimethyl- versus 1-methyl,1-phenyl-substituted epoxides (9 and 8, Figure 3) with methyl thiolate as a model soft nucleophile were briefly considered using the PDDG/PM3 semi-empirical method. This method has shown to yield reasonably accurate energetics for oxiranes-opening reactions at low computational cost.75 Free energy barriers were calculated using transition states optimized with the Berny algorithm; all transition structures were verified to have only one negative eigenvalue in their diagonalized force-constant matrices, and their associated eigenvectors were confirmed to correspond to motion along the reaction coordinate. For hydroquinones, the molecular mechanisms considered were i) reaction between GSH and semiquinone radicals and ii) enzymatic and non-enzymatic redox cycling (Figure 4). Free 10 ACS Paragon Plus Environment

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energies of conjugation between GSH and phenoxy radicals for HQ vs. tBHQ were contrasted with M06-HF/6-31+G(d); supporting frontier molecular orbital energy calculations were carried out using the mPW1PW91 density functional with the MIDIX+ basis set. In order to gauge electrostatics of enzyme-ligand interactions in Cytochrome P450 oxidoreductase (POR)-assisted redox cycling,76 the binding poses of tertbutylbenzoquinone (tBQ) and unsubstituted 1,4-benzoquinone (BQ) were evaluated using Autodock Vina.77 Binding affinities were computed using the AMBER force field based on the 5URD X-ray structure of POR. In all ground-state electronic structure calculations, geometries were fully optimized, and all minima were verified to have no imaginary vibrational frequencies. Enthalpies and free energies were evaluated in gas phase at 298 K, including changes in vibrational energy. Calculations were performed using Gaussian g09 software.78

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Results The effects of the seven chemicals tested on cell viability, GSH levels and changes in the expression of Gclc, Gclm, Hmox1, and Nqo1 mRNAs were evaluated in the two Hepa-1 derived liver cell lines. Gclm and Gclc transfected CR cells have increased glutamate-cysteine ligase (GCL) activity and thus enhanced GSH synthesis compared to the standard HV cells.69 We confirmed that CR cells have increased GCLC and GCLM mRNA (below) and protein expression relative to that of HV cells (Figure S2). The assays performed on the test chemical set (Figure 2) are summarized in Table 1. Antioxidant gene expression for Gclc, Glcm, Hmox1 and Nqo1 mRNAs was measured by RT-qPCR for all chemicals at 24 hr. The mRNA-induction effects of peroxides and hydroquinones (chemicals 1 – 4) were also measured at 6 hr. Similarly, GSH assays were performed for all chemicals at 24 hr, and for select chemicals at 6 hr. The MTT cell viability assay (based on the activity of mitochondrial dehydrogenases) was performed for all chemicals. Cell viability. All seven chemicals showed dose-depended changes in cell viability in both control HV cells and CR cells (Figure 5), with large concentration-response differences between the cell lines’ chemical viability thresholds (as defined by their AC50) are summarized in Table 2. In order from lowest to highest AC50 the chemicals conformed to the following trend: 6 > 4 > 5 > 7 > 3 > 1 > 2 (Figure 6). The trend was identical in both cell lines (rank correlation = 1). Overall, CR cells were more resistant to adverse effects on viability, as indicated by higher AC50 values. If we define ∆AC50 as the difference of MTT AC50 between the HV cell line and the CR cell line, the ∆AC50 observed for each chemical from highest to lowest follows the trend: 2 > 3 > 1 = 4 > 5 > 7 > 6 (Figure 7). This trend is generally consistent with the more potent chemicals (smallest AC50) exhibiting larger differences in AC50 between the two cell lines. 12 ACS Paragon Plus Environment

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Antioxidant gene mRNA expression. mRNA expression for Nqo1, Hmox1, Gclc, and Gclm, was assessed by RT-qPCR in response to sublethal chemical exposure (40% of LC50). Twenty-four hours after exposure to chemicals 1, 3, 4, and 6, significant upregulation was observed in Nqo1, Hmox1, and Gclm in both cell lines (Figure 8). In addition, Nqo1 expression was upregulated 24hr after exposure to BPA (5), but only for HV cells (Figure 8A). Chemicals 1, 3, and 4 induced Gclc expression in the HV cell line only. Dinoseb (6) was the only chemical to significantly upregulate Gclc in both cell lines (Figure 8C). GCLC and GCLM protein expression was greater in CR cells than HV cells when treated with vehicle only, and HQ treatment increased GCLM protein expression in HV cells (Figure S2). There was also a correlation between Gclc and Gclm mRNA expression and their respective protein levels among control, HQ and PFOA treatments, in both HV and CR cell lines (Figure S3). While there were also correlations between GSH content and GCLC and GCLM protein levels, especially in the case of HV cells and GCLC protein expression (R2=0.87; Figure S4, panel A), there are many other factors that determine GSH content in addition to GCL expression and activity, including cysteine/cystine import, GSH synthetase levels, GSSG reductase activity, GSH and GSSG export pumps, and other factors associated with oxidative stress and GSH conjugation reactions91. The four chemicals tested at 6 hr (1 – 4) showed upregulation of Nqo1, Hmox1, and Gclm mRNA expression compared to vehicle-treated controls. With the exception of induction of Gclm in the CR line by CHP (1), the upregulation of genes by the test chemicals relative to controls was statistically significant (p < 0.05) (Figure 8A-B, D). In contrast, all chemicals except for the two hydroquinones (3 and 4) failed to significantly upregulate Gclc expression (Figure 8C).

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Modified ToxPi charts79 visually summarize the expression profiles for each chemical (Figure 9) and demonstrated that, in concordance with the statistical results, CHP (1) and hydroquinones (3 and 4) exhibited the most drastic effects, while PFOA (7) a BPA (5) had minor effects on antioxidant gene mRNA expression. MANOVA analysis was used to quantify the differences in chemical effects on the relative antioxidant gene mRNA expression between the HV and the CR cells and showed that mRNA expression profiles differed significantly for 3 (p=0.0005), 4 (p=0.023), and 5 (p=0.028) (Table S1). Specifically, HQ-induced Gclc (6 hr) and Hmox1 (6 and 24 hr) mRNA levels were significantly higher in the HV cells, as were tBHQinduced Gclc (6 hr), Gclm and Hmox1 (6 and 24 hr), and Nqo1 (24 hr) mRNA levels (Table S2). In contrast, PFOA (7) and Dinoseb (6) induced similar mRNA expression in the two cell lines, with Pillai’s trace < 0.3 (Table S2). Temporal changes in antioxidant gene mRNA expression. We further investigated the changes in antioxidant gene mRNA expression over time for compounds 1 – 4 with MANOVA Pilli’s trace for significance. Gclc mRNA response to chemicals 1 – 4 in the HV cell line decreases significantly from 6 to 24 hr (p=0.036). Similarly, Gclm and Hmox1 mRNA induction decreased significantly from 6 to 24 hr in the CR cell line (p=0.046 and 0.006). In contrast, Nqo1 mRNA expression increased significantly (p=0.002) from 6 to 24 hr for both cell lines after exposure to all seven chemicals (Table S3). The pattern can be attributed to HQ and tBHQ as these chemicals significantly increased Nqo1 induction from 6 to 24 hr (based on two-sample ttests, Table S4). Glutathione levels. HQ and tBHQ had significant effects on GSH levels at 6 hr (Figure 10). At 40% of the LC50, HQ decreased GSH levels in both HV and CR cell lines (p=0.068 and 0.040, respectively), while tBHQ upregulated GSH levels in the CR cell line at 6 hr (p=0.009). 14 ACS Paragon Plus Environment

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Twenty-four hours after HQ and tBHQ treatment the intracellular GSH levels were increased in both CR and HV cell lines (Figure 10). Given the observed dependence between GSH and antioxidant gene induction, we further investigated the effect of Gclm mRNA expression on the difference in intracellular GSH concentration from 6 to 24 hr. Figure 11 shows the approximately quadratic relationship between Gclm mRNA induction at 6 hr and differences in GSH expression over time. Chemicals that upregulated Gclm mRNA at 6 hr above 3-fold also upregulated intracellular GSH at 24 hr, regardless of the cell line. An induction GCLC and GCLM proteins in HV cells following treatment with PFOA and HQ, (Figure S2) was associated with higher GSH levels in HV cells (R2=0.87 for GCLC; R2=0.28 for GCLM), but was this association was weaker in CR cells (R2=0.24 for GCLC; R2=0.07 for GCLM). Intracellular glutathione and viability. Next, we investigated the relationship between the chemicals’ effects on intracellular GSH and the associated differences in cytotoxicity between HV and CR cell lines. Overall, the difference in cytotoxicity between cell lines is inversely correlated with GSH levels in the CR cell line at 24 hr (Figure 12). Peroxides, particularly lowmolecular weight tBHP (2), behave as an outlier, likely due to rapid metabolism80 and decreased antioxidant effects at 24 hr (Table S4). Gene co-expression. Transcriptional responses 24 hr after exposure to compounds 1 – 7, and 6 hr after exposure to compounds 1 – 4 were highly correlated in both HV and CR cell lines (Figures 13A and 13C). Clustering analysis based on pairwise complete correlation showed that mRNA expression was significantly grouped by time in the HV cell line (Figure 13B). In the CR cell line, mRNA expression was correlated across time points. However, Nqo1 (6 hr) formed a distinct sub cluster with Gclc (6 hr) with a highly significant positive correlation (Figure 13C-D, 15 ACS Paragon Plus Environment

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R=1, p 0.76) in the HV cell line (Figure 13A); a particularly strong association was seen with Nqo1 mRNA expression (R= -0.99, p

>

OH (6) DNSB

(4) tBHQ

OH (5) BPA

F F F

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OH F

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(2) tBHP

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Figure 7 OH O

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F F F

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Figure 8

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Figure 9

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Figure 10

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Figure 11

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Figure 12

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Figure 13

68 ACS Paragon Plus Environment

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Figure 14

3.5 3

Major tBHQ pathway

2.5

kcal/mol

ΔGHQ – ΔGtBHQ

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Chemical Research in Toxicology

Minor tBHQ pathway

2 1.5 1 0.5 0 -0.5

69 ACS Paragon Plus Environment

Chemical Research in Toxicology 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

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Figure 15

70 ACS Paragon Plus Environment

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Chemical Research in Toxicology

Figure 16

HV Cell Line

CR Cell Line

71 ACS Paragon Plus Environment